Mobile X-ray imaging apparatus

ABSTRACT

Disclosed herein is a mobile x-ray imaging apparatus having an improved structure to reinforce security of an x-ray detector. A mobile x-ray imaging apparatus includes an x-ray source configured to generate and radiate x-rays, one or more x-ray detectors provided to detect the x-rays radiated from the x-ray source, a storage unit having one or more slots in which the one or more x-ray detectors are stored, and one or more locking units installed in the storage unit to limit withdrawal of the one or more x-ray detectors stored in the one or more slots, wherein the one or more locking units may include a pressing member provided to be pressable and one or more rotating members configured to directly receive a pressing force of the pressing member and provided to rotate and protrude toward an inside of the one or more slots.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application claims priority under 35 U.S.C. § 365 toInternational Patent Application No. PCT/KR2016/010756 filed Sep. 26,2016, entitled “MOBILE X-RAY IMAGING APPARATUS”, and, throughInternational Patent Application No. PCT/KR2016/010756, to Korean PatentApplication No. 10-2015-0180778 filed Dec. 17, 2015, each of which areincorporated herein by reference into the present disclosure as if fullyset forth herein.

TECHNICAL FIELD

The present disclosure relates to a mobile x-ray imaging apparatus, andmore particularly, to a mobile x-ray imaging apparatus having animproved structure to reinforce security of an x-ray detector.

BACKGROUND ART

An x-ray imaging apparatus is an apparatus using x-rays to obtain animage of an inside of an object. An x-ray imaging apparatus mayirradiate an object with x-rays and detect x-rays that have passedthrough the object to form an image of an inside of the object with anon-invasive method. A medical x-ray imaging apparatus may be used indiagnosing an injury, a disease, or the like that cannot be diagnosedfrom outside.

A typical x-ray imaging apparatus has an x-ray source and an x-raydetector fixed at a predetermined space. Consequently, a patient has tomove to an examination room in which an x-ray imaging apparatus isdisposed to perform x-ray imaging.

However, because it is difficult to perform x-ray imaging using atypical x-ray imaging apparatus in a case of a patient having mobilitydifficulties, a mobile x-ray imaging apparatus capable of performingx-ray imaging regardless of location has been developed.

Because a mobile x-ray imaging apparatus has an x-ray source mounted ata movable main body and uses a portable x-ray detector, x-ray imagingmay be performed by directly going to a patient having mobilitydifficulties.

One or more x-ray detectors may be stored in a mobile x-ray imagingapparatus. Due to a characteristic of a mobile x-ray imaging apparatusbeing usable in various locations, there are concerns regarding a theftor security problem. Particularly, the one or more x-ray detectors aremore vulnerable to a theft or security problem due to being portable.

DISCLOSURE Technical Problem

It is an aspect of the present disclosure is to provide a mobile x-rayimaging apparatus having an improved structure to prevent theft of anx-ray detector and reinforce security.

It is another aspect of the present disclosure to provide a mobile x-rayimaging apparatus having an improved structure to enable one or morex-ray detectors to be separately locked.

It is still another aspect of the present disclosure to provide a mobilex-ray imaging apparatus having an improved structure to enable one ormore x-ray detectors to be simultaneously locked.

Technical Solution

A mobile x-ray imaging apparatus according to a spirit of the presentdisclosure includes an x-ray source configured to generate and radiatex-rays, one or more x-ray detectors provided to detect the x-raysradiated from the x-ray source, a storage unit having one or more slotsin which the one or more x-ray detectors are stored, and one or morelocking units installed in the storage unit to limit withdrawal of theone or more x-ray detectors stored in the one or more slots, wherein theone or more locking units may include a pressing member provided to bepressable and one or more rotating members configured to directlyreceive a pressing force of the pressing member and provided to rotateand protrude toward an inside of the one or more slots.

The pressing member may vertically move in a first direction, and theone or more rotating members may rotate about a rotation shaft extendingin a second direction.

The one or more locking units may further include a rotation limitingunit configured to limit rotation of the one or more rotating members,and the rotation limiting unit may face the pressing member and the oneor more rotating members are placed therebetween.

The rotation limiting unit may include a rod configured to verticallymove in the first direction, which is the same as a moving direction ofthe pressing member, and a solenoid coupled to the rod to adjustmovement of the rod according to an electrical signal.

Each of the one or more rotating members may include a rod-correspondingsurface configured to face the rod, and one end portion of the rodfacing the rod-corresponding surface may move along therod-corresponding surface when the one or more rotating members rotate.

A locking groove configured to limit rotation of the one or morerotating members by the one end portion of the rod being insertedthereinto may be formed to be recessed at the rod-corresponding surface.

The rod-corresponding surface may include a first portion disposed infront of a second portion in a direction in which the one or morerotating members rotate by being pressed by the pressing member and thesecond portion disposed behind the first portion in the direction inwhich the one or more rotating members rotate by being pressed by thepressing member, and formed above the first portion in the firstdirection.

A locking groove configured to limit rotation of the one or morerotating members by the one end portion of the rod being insertedthereinto may be formed to be recessed at the second portion.

The rod-corresponding surface may further include a third portionconfigured to connect the first portion to the second portion and betilted toward the second portion in the first direction.

The rotation limiting unit may further include a casing configured tohave the rod and the solenoid mounted therein and have a rod guideformed at one sidewall thereof, and a stopper that is formed to protrudefrom the rod may be configured to move vertically in the first directionand be coupled to the rod guide to limit vertical movement of the rod.

The pressing member may move along a guide pin coupled to the pressingmember to guide movement of the pressing member, and a first elasticmember configured to be repeatedly contracted and relaxed according tomovement of the pressing member may be provided at the guide pin.

The one or more rotating members may rotate about a rotation shaftconfigured to pass through the one or more rotating members, and asecond elastic member configured to be repeatedly contracted and relaxedaccording to rotation of the one or more rotating members may beprovided at the rotation shaft.

The one or more locking units may further include a connecting memberconfigured to connect the pressing member to the rotation limiting unitand have a guide pin through-hole through which the guide pin passesformed therein.

The one or more locking units may further include a support memberinstalled at a partition configured to divide the one or more slots, andthe rotation shaft may pass through the support member and the one ormore rotating members.

The second elastic member may include a torsion spring, one end portionof the second elastic member may be fixed to one sidewall of the supportmember, and the other end portion of the second elastic member may befixed to a protrusion formed at one surface of each of the one or morerotating members facing the one sidewall of the support member to whichthe one end portion of the second elastic member is fixed.

A mobile x-ray imaging apparatus according to a spirit of the presentdisclosure includes a main body, an x-ray source configured to generateand radiate x-rays, one or more x-ray detectors provided to detect thex-rays radiated from the x-ray source, a storage unit provided in themain body and having one or more slots in which the one or more x-raydetectors are stored, and one or more locking units installed in thestorage unit to limit withdrawal of the one or more x-ray detectorsstored in the one or more slots, wherein the one or more locking unitsmay include a pressing member provided to be pressable and configured tovertically move in a first direction, one or more rotating membersprovided to rotate about a rotation shaft extending in a seconddirection and protrude toward the one or more slots, and a rotationlimiting unit including a rod vertically moving in the first directionto limit rotation of the one or more rotating members.

A pressing force of the pressing member may be directly transmitted tothe one or more rotating members.

Each of the one or more rotating members may include a rod-correspondingsurface configured to face the rod, and a locking groove configured tolimit rotation of the one or more rotating members by one end portion ofthe rod facing the rod-corresponding surface being inserted thereintomay be formed to be recessed at the rod-corresponding surface.

The rotation shaft may pass through the one or more rotating members inthe second direction, and, when the pressing member is pressed, therotation shaft may be placed above the locking groove in the firstdirection by rotation of the one or more rotating members.

The rod-corresponding surface may include a first portion disposed infront of a second portion in a direction in which the one or morerotating members rotate by being pressed by the pressing member and thesecond portion disposed behind the first portion in the direction inwhich the one or more rotating members rotate by being pressed by thepressing member, formed above the first portion in the first direction,and having the locking groove formed to be recessed therein.

The rod-corresponding surface may further include a third portionconfigured to connect the first portion to the second portion and betilted toward the second portion in the first direction.

A slope may be formed rearward in the direction in which the one or morerotating members rotate with respect to the first direction at the onesurface of the rod facing the rod-corresponding surface.

The pressing member may move along a guide pin coupled to the pressingmember to guide movement of the pressing member, and a first elasticmember configured to be repeatedly contracted and relaxed according tomovement of the pressing member may be provided at the guide pin.

The one or more rotating members may rotate about the rotation shaftconfigured to pass through the one or more rotating members, and asecond elastic member configured to be repeatedly contracted and relaxedaccording to rotation of the one or more rotating members may beprovided at the rotation shaft.

The second elastic member may include a torsion spring.

A third elastic member configured to be repeatedly contracted andrelaxed in the first direction according to movement of the rod may beprovided at the rod. The third elastic member may be relaxed when thefirst elastic member is contracted, and the third elastic member may becontracted when the first elastic member is relaxed.

The one or more rotating members may rotate and protrude toward aninside of the one or more slots when a pressing force is transmittedfrom the pressing member.

A mobile x-ray imaging apparatus according to a spirit of the presentdisclosure includes an x-ray source configured to generate and radiatex-rays, a plurality of x-ray detectors provided to detect the x-raysradiated from the x-ray source, a storage unit having a plurality ofslots in which the plurality of x-ray detectors are stored, and alocking unit installed at the storage unit to simultaneously limitwithdrawal of the plurality of x-ray detectors stored in the pluralityof slots.

The plurality of slots may include a first slot and a second slotconfigured to abut the first slot, and a partition is placedtherebetween, and the locking unit may be installed at the partition tosimultaneously limit withdrawal of the plurality of x-ray detectorsstored in the first slot and the second slot.

The plurality of slots may include a first slot and a second slot thatare adjacent to each other, and the locking unit may include a pressingmember provided to be pressable and a plurality of rotating membersincluding a first rotating member provided to rotate and protrude towardan inside of the first slot and a second rotating member provided torotate and protrude toward an inside of the second slot.

A pressing force of the pressing member may be directly transmitted tothe plurality of rotating members.

The pressing member may simultaneously press the plurality of rotatingmembers.

The locking unit may further include a rotation limiting unit includinga rod configured to linearly move to simultaneously limit rotation ofthe plurality of rotating members.

Advantageous Effects

Since one or more locking units are installed in a storage unit to limitwithdrawal of one or more x-ray detectors stored in one or more slots,theft of the one or more x-ray detectors can be prevented whilereinforcing security at the same time.

Since a plurality of locking units are installed in the storage unit,withdrawal of a plurality of x-ray detectors stored in a plurality ofslots can be separately limited.

Since a single pressing member and a single rotation limiting unit areused to simultaneously adjust rotation of a plurality of rotatingmembers, withdrawal of the plurality of x-ray detectors stored in theplurality of slots adjacent to each other can be separately limited.

DESCRIPTION OF DRAWINGS

These and/or other aspects of the disclosure will become apparent andmore readily appreciated from the following description of theembodiments, taken in conjunction with the accompanying drawings ofwhich:

FIG. 1 is a view illustrating a usage example of a mobile x-ray imagingapparatus according to an embodiment of the present disclosure;

FIG. 2 is a perspective view illustrating a storage unit of the mobilex-ray imaging apparatus according to an embodiment of the presentdisclosure;

FIG. 3 is a perspective view illustrating the storage unit at adifferent angle from FIG. 2 so that an arrangement structure of alocking unit in the mobile x-ray imaging apparatus according to anembodiment of the present disclosure is visible;

FIG. 4 is a perspective view illustrating the locking unit of the mobilex-ray imaging apparatus according to an embodiment of the presentdisclosure;

FIG. 5 is an exploded perspective view illustrating the locking unit ofthe mobile x-ray imaging apparatus according to an embodiment of thepresent disclosure;

FIGS. 6A to 6C are views illustrating an operational process of thelocking unit for locking a slot in the mobile x-ray imaging apparatusaccording to an embodiment of the present disclosure;

FIGS. 7A and 7B are views illustrating an operational process of thelocking unit for unlocking a slot in the mobile x-ray imaging apparatusaccording to an embodiment of the present disclosure;

FIG. 8 is a perspective view illustrating a storage unit of the mobilex-ray imaging apparatus according to another embodiment of the presentdisclosure;

FIG. 9 is a perspective view illustrating a locking unit of the mobilex-ray imaging apparatus according to another embodiment of the presentdisclosure;

FIG. 10 is an exploded perspective view illustrating the locking unit ofthe mobile x-ray imaging apparatus according to another embodiment ofthe present disclosure;

FIG. 11 is a view illustrating the locking unit when a slot in themobile x-ray imaging apparatus according to another embodiment of thepresent disclosure is locked; and

FIG. 12 is a view illustrating the locking unit when a slot in themobile x-ray imaging apparatus according to another embodiment of thepresent disclosure is unlocked.

MODE FOR INVENTION

Hereinafter, an exemplary embodiment according to the present disclosurewill be described in detail with reference to the accompanying drawings.Meanwhile, terms, such as “front end,” “rear end,” “upper portion,”“lower portion,” “upper end,” and “lower end,” that are used in thedescription below are defined on the basis of the drawings, and a shapeand a position of each element is not limited by the terms.

FIG. 1 is a view illustrating a usage example of a mobile x-ray imagingapparatus according to an embodiment of the present disclosure.Hereinafter, reference numeral “3” refers to an object to be x-rayed.Here, the object may be a living body of a human being or an animal, butis not limited thereto. The object may be anything that may have animage of an inner structure thereof formed by a mobile x-ray imagingapparatus 1.

As illustrated in FIG. 1, the mobile x-ray imaging apparatus 1 mayinclude a main body 10. The main body 10 may be movable. A controller(not illustrated) may be provided in the main body 10. The controllermay control an x-ray source 20 to control generation of x-rays. Also,the controller may receive an electrical signal from one or more x-raydetectors 30 and generate an x-ray image.

The mobile x-ray imaging apparatus 1 may further include a hand switch40. The hand switch 40 may receive a command from a user and transmitthe command to the controller. A command received by the hand switch 40may include an x-ray radiation readying command or an x-ray radiatingcommand. For example, a user may input the x-ray irradiation readyingcommand through the hand switch 40 for capturing by the mobile x-rayimaging apparatus 1. Also, when preparation for capturing is finished,the user may input the x-ray radiating command through the hand switch40 so that the x-ray source 20 radiates x-rays.

The mobile x-ray imaging apparatus 1 may further include a plurality ofwheels 50 configured 2 a to give mobility to the main body 10.

The mobile x-ray imaging apparatus 1 may further include a display 60.The display 60 may display information on a patient, an x-ray image, andthe like. The display 60 may be installed at the main body 10. Thedisplay 60 may include a touch screen function.

The mobile x-ray imaging apparatus 1 may further include a handle 70provided at the main body 10. A user may grip the handle 70 and push orpull the main body 10.

The mobile x-ray imaging apparatus 1 may further include a support arm80 and a support frame 90. The x-ray source 20 that will be describedbelow may be mounted on the movable main body 10 by the support arm 80.The support arm 80 may be mounted on the support frame 90 to berotatable in a vertical direction. The support frame 90 may be mountedat one side of the main body 10 to be rotatable in a horizontaldirection. As a result, since the support arm 80 is rotatable and a tiltangle thereof may be changed, the x-ray source 20 may freely move.

The mobile x-ray imaging apparatus 1 may further include the x-raysource 20 configured to generate and radiate x-rays. As described above,the x-ray source 20 may be coupled to the support arm 80. The x-raysource 20 receives power and generates x-rays. Energy of x-rays may becontrolled by a tube voltage, and intensity and dose of x-rays may becontrolled by a tube current and x-ray exposure time.

The mobile x-ray imaging apparatus 1 may further include the one or morex-ray detectors 30 provided to detect x-rays radiated from the x-raysource 20. The one or more x-ray detectors 30 may have various sizesdepending on an object of x-ray image capturing. The one or more x-raydetectors 30 may be wirelessly realized for convenience of use. The oneor more x-ray detectors 30 may be stored in a storage unit 100 aftercapturing an x-ray image. Also, the one or more x-ray detectors 30 maybe charged while being stored in the storage unit 100.

The mobile x-ray imaging apparatus 1 may further include the storageunit 100 configured to store the one or more x-ray detectors 30. Thestorage unit 100 may be provided at the main body 10. The storage unit100 will be described in detail below.

The mobile x-ray imaging apparatus 1 may further include one or morelocking units 200 configured to limit withdrawal of the one or morex-ray detectors 30 stored in the storage unit 100. The one or morelocking units 200 will be described in detail below.

FIG. 2 is a perspective view illustrating a storage unit of the mobilex-ray imaging apparatus according to an embodiment of the presentdisclosure, and FIG. 3 is a perspective view illustrating the storageunit at a different angle from FIG. 2 so that an arrangement structureof a locking unit in the mobile x-ray imaging apparatus according to anembodiment of the present disclosure is visible. In FIG. 3, someconfigurations of a partition 130 are omitted so that an arrangementstructure of the one or more locking units 200 is seen well.

As illustrated in FIGS. 2 and 3, the storage unit 100 may include one ormore slots 110 and 120 in which the one or more x-ray detectors 30 arestored.

Sizes of the one or more slots 110 and 120 may be different from eachother. The sizes of the one or more slots 110 and 120 are determinedaccording to sizes of the one or more x-ray detectors 30 stored in theone or more slots 110 and 120. For example, the one or more slots 110and 120 may include a first slot 110 configured to store an x-raydetector having a relatively small size and a second slot 120 configuredto store an x-ray detector having a relatively large size.

The first slot 110 and the second slot 120 may abut each other and thepartition 130 is placed there between. The partition 130 may be formedto extend from a sidewall of a storage unit body 101 configured to forman exterior of the storage unit 100 toward an inside of the storage unit100. The second slot 120 may be defined by the partition 130 and a frame140. The frame 140 may be formed to extend from the sidewall of thestorage unit body 101 toward the inside of the storage unit 100 to bespaced a predetermined distance apart from the partition 130. The frame140 and the partition 130 may be parallel to each other.

Sizes of the one or more slots 110 and 120 are not limited to beingdifferent from each other and may be modified in various ways. Forexample, sizes of the one or more slots 110 and 120 may be the same.Also, the number of the one or more slots 110 and 120 is not limited totwo. However, a case in which the one or more slots 110 and 120 includethe first slot 110 and the second slot 120 will be mainly described asan example.

The mobile x-ray imaging apparatus 1 may further include the one or morelocking units 200 installed in the storage unit 100 to limit withdrawalof the one or more x-ray detectors 30 stored in the one or more slots110 and 120.

The one or more locking units 200 may separately limit withdrawal of theone or more x-ray detectors 30 stored in the one or more slots 110 and120. Specifically, the one or more locking units 200 may include a firstlocking unit 200 a configured to limit withdrawal of an x-ray detectorstored in the first slot 110 and a second locking unit 200 b configuredto limit withdrawal of an x-ray detector stored in the second slot 120.

The one or more locking units 200 may be installed in the storage unit100. For example, the first locking unit 200 a may be installed in thepartition 130. Specifically, the first locking unit 200 a may beinstalled in the partition 130 so that a portion thereof is exposed tothe outside. The second locking unit 200 b may be installed in the frame140. Specifically, the second locking unit 200 b may be installed in theframe 140 so that a portion thereof is exposed to the outside. Whendescribed according to another aspect, the one or more locking units 200may be installed in the storage unit 100 to be adjacent to inlets of theone or more slots 110 and 120.

FIG. 4 is a perspective view illustrating the locking unit of the mobilex-ray imaging apparatus according to an embodiment of the presentdisclosure, and FIG. 5 is an exploded perspective view illustrating thelocking unit of the mobile x-ray imaging apparatus according to anembodiment of the present disclosure. Hereinafter, unmarked elementsrefer to FIGS. 1 to 3.

As illustrated in FIGS. 4 and 5, the one or more locking units 200 mayinclude a pressing member 210. The pressing member 210 may be providedto be pressable. The pressing member 210 may vertically move in a firstdirection A. In other words, the pressing member 210 may linearly movein the first direction A. The pressing member 210 may move along a guidepin 213. The guide pin 213 may extend in the first direction A to guidemovement of the pressing member 210. The guide pin 213 may be coupled tothe pressing member 210.

The one or more locking units 200 may further include one or morerotating members 220. A pressing force of the pressing member 210 may bedirectly transmitted to the one or more rotating members 220. Sinceelements configured to mechanically connect the pressing member 210 tothe one or more rotating members 220 may be omitted when the one or morelocking units 200 are designed so that the pressing force of thepressing member 210 may be directly transmitted to the one or morerotating members 220 as described above, miniaturization and structuralsimplification of the one or more locking units 200 may be realized.

The one or more rotating members 220 may be provided to rotate andprotrude toward an inside of the one or more slots 110 and 120. Forexample, a rotating member 220 of the first locking unit 200 a mayrotate and protrude toward the inside of the first slot 110. A rotatingmember 220 of the second locking unit 200 b may rotate and protrudetoward the inside of the second slot 120. The one or more rotatingmembers 220 may rotate about a rotation shaft 229 configured to extendin a second direction B. The rotation shaft 229 may pass through the oneor more rotating members 220 in the second direction B. The firstdirection A and the second direction B may be perpendicular to eachother.

Each of the one or more rotating members 220 may include a pressingportion 221 provided to be pressed by the pressing member 210. Each ofthe one or more rotating members 220 may further include a rotationlimiting portion 222 provided to limit rotation of the one or morerotating members 220. The pressing portion 221 and the rotation limitingportion 222 may have shapes that protrude toward the pressing member 210in the first direction A. The rotation limiting portion 222 may beprovided in front of the pressing portion 221 in a direction R in whichthe one or more rotating members 220 rotate by being pressed by thepressing member 210. The pressing portion 221 may face a lower surface211 of the pressing member 210 (see FIG. 6A), and the rotation limitingportion 222 may face a front surface 212 of the pressing member 210 inthe direction R in which the one or more rotating members 220 rotate bybeing pressed by the pressing member 210 (see FIG. 6A).

Each of the one or more rotating members 220 may further include arod-corresponding surface 225 configured to face a rotation limitingunit 230. Specifically, each of the one or more rotating members 220 mayfurther include the rod-corresponding surface 225 configured to face arod 231. One end portion of the rod 231 facing the rod-correspondingsurface 225 may move along the rod-corresponding surface 225 when theone or more rotating members 220 rotate. A locking groove 227 configuredto limit rotation of the one or more rotating members 220 by the one endportion of the rod 231 being inserted thereinto may be formed to berecessed at the rod-corresponding surface 225.

The rod-corresponding surface 225 may include a first portion 225 adisposed in front of a second portion 225 b in the direction R in whichthe one or more rotating members 220 rotate by being pressed by thepressing member 210 (see FIG. 6A). Also, the rod-corresponding surface225 may further include a second portion 225 b disposed behind the firstportion 225 a in the direction R in which the one or more rotatingmembers 220 rotate by being pressed by the pressing member 210 (see FIG.6A). The second portion 225 b may be formed above the first portion 225a in the first direction A. The locking groove 227 may be formed to berecessed at the second portion 225 b. Also, the rod-correspondingsurface 225 may further include a third portion 225 c configured toconnect the first portion 225 a to the second portion 225 b (see FIG.6A). The third portion 225 c may be tilted toward the second portion 225b in the first direction A on the basis of a state in which the one ormore slots 110 and 120 are unlocked. A slope may be formed rearward inthe direction R in which the one or more rotating members 220 rotatewith respect to the first direction A at one surface 231 a of the rod231 facing the rod-corresponding surface 225. Consequently, the rod 231may smoothly pass through the third portion 225 c while the one surface231 a of the rod 231 is in contact with the third portion 225 c when theone or more rotating members 220 rotate.

The one or more rotating members 220 may also be integrally formed withthe pressing member 210.

The one or more locking units 200 may further include the rotationlimiting unit 230 configured to limit the rotation of the one or morerotating members 220. The rotation limiting unit 230 may face thepressing member 210 and the one or more rotating members 220 may beplaced therebetween.

The rotation limiting unit 230 may include the rod 231. The rod 231 mayvertically move in the first direction A which is the same as a movingdirection of the pressing member 210. In other words, the rod 231 maylinearly move in the first direction A which is the same as the movingdirection of the pressing member 210.

The rotation limiting unit 230 may further include a solenoid 233coupled to the rod 231 to adjust movement of the rod 231 according to anelectrical signal. The solenoid 233 may be connected via a cable 239 toa controller configured to control whether the solenoid 233 is operated.The solenoid 233 may mostly operate during a process in which the one ormore slots 110 and 120 are being unlocked. That is, when a user inputs acommand for unlocking the one or more slots 110 and 120, the rod 231moves downward in the first direction A when the solenoid 233 isoperated. Accordingly, the one end portion of the rod 231 is detachedfrom the locking groove 227, and the one or more rotating members 220are restored to a state of before being pressed by the pressing member210. Consequently, the one or more slots 110 and 120 are unlocked. Auser may input a password or use a radiofrequency (RF) card to commandthe one or more slots 110 and 120 to be unlocked.

The rotation limiting unit 230 may further include a casing 234configured to have the rod 231 and the solenoid 233 mounted therein. Arod guide 235 may be formed at one sidewall 234 a of the casing 234. Therod guide 235 may have a shape that extends in the first direction A tolimit movement of the rod 231. A stopper 232 configured to protrude fromthe rod 231 may be formed at the rod 231. Movement of the rod 231 may belimited by interference between the stopper 232 and the rod guide 235.The stopper 232 formed to protrude from the rod 231 may vertically movein the first direction A and be coupled to the rod guide 235 to limitvertical movement of the rod 231.

The one or more locking units 200 may further include a connectingmember 240 configured to connect the pressing member 210 to the rotationlimiting unit 230. Specifically, the connecting member 240 may connectthe pressing member 210 to the casing 234. A guide pin through-hole 241through which the guide pin 213 passes may be formed at the connectingmember 240. That is, the guide pin 213 may pass through the guide pinthrough-hole 241 in the first direction A and may be coupled to thepressing member 210.

The one or more locking units 200 may further include a support member250 installed in the storage unit 100. For example, the support member250 of the first locking unit 200 a may be installed in the partition130 configured to divide the one or more slots 110 and 120. The supportmember 250 of the second locking unit 200 b may be installed at theframe 140.

The support member 250 may include an installing portion 251 installedin the storage unit 100. Also, the support member 250 may furtherinclude a plurality of ribs 252 extending forward in the direction R inwhich the one or more rotating members 220 rotate by being pressed bythe pressing member 210. A rotation shaft coupling hole 253 may beformed at the plurality of ribs 252. The rotation shaft 229 may passthrough the support member 250 and the one or more rotating members 220.Specifically, the rotation shaft 229 may pass through the rotation shaftcoupling hole 253 of the support member 250 and a rotation shaftthrough-hole 228 formed at each of the one or more rotating members 220.The connecting member 240 may be fixed and coupled to the support member250 by a fixing member 260 configured to pass through a fixing hole 254formed at the installing portion 251. The casing 234 may be fixed andcoupled to the support member 250 by an engaging member 270 configuredto pass through an engaging hole 255 formed at the plurality of ribs 252of the support member 250. The fixing member 260 and the engaging member270 may include, for example, a screw.

The one or more locking units 200 may further include a first elasticmember 280. The first elastic member 280 may include a tensile springconfigured to be repeatedly contracted and relaxed in the firstdirection A. The first elastic member 280 may be provided at the guidepin 213 and repeatedly be contracted and relaxed according to movementof the pressing member 210. Specifically, when the pressing member 210moves downward in the first direction A, the first elastic member 280may be contracted. Conversely, when the pressing member 210 moves upwardin the first direction A, the first elastic member 280 may be relaxed.The pressing member 210 may be restored to a state of before beingpressed by a restoration force of the first elastic member 280.

The one or more locking units 200 may further include a second elasticmember 290. The second elastic member 290 may include a torsion springconfigured to be repeatedly contracted and relaxed according to rotationof the one or more rotating members 220. The second elastic member 290may be provided at the rotation shaft 229. One end portion of the secondelastic member 290 may be fixed to one sidewall of the support member250. Specifically, the one end portion of the second elastic member 290may be inserted into a hole 256 formed at the plurality of ribs 252 andfixed. The other end portion of the second elastic member 290 may befixed to a protrusion 221 a formed at each of the one or more rotatingmembers 220 or may be supported by the protrusion 221 a. The protrusion221 a may be formed to protrude from the one sidewall of the supportmember 250 to which the one end portion of the second elastic member 290is fixed, i.e., one surface of each of the one or more rotating members220 facing the plurality of ribs 252 of the support member 250 to whichthe one end portion of the second elastic member 290 is fixed. Whendescribed according to another aspect, the protrusion 221 a may extendfrom the pressing portion 221 of each of the one or more rotatingmembers 220 in the second direction B to face the plurality of ribs 252of the support member 250 to which the one end portion of the secondelastic member 290 is fixed. When the one or more rotating members 220are pressed by the pressing member 210, the second elastic member 290may be contracted. Conversely, when the one or more rotating members 220are not pressed by the pressing member 210, the second elastic member290 may be relaxed. The one or more rotating members 220 may be restoredto a state of before being pressed by a restoration force of the secondelastic member 290.

The one or more locking units 200 may further include a third elasticmember 300. The third elastic member 300 may include a tensile springconfigured to be repeatedly contracted and relaxed in the firstdirection A. The third elastic member 300 may be provided at the rod 231and be repeatedly contracted and relaxed in the first direction Aaccording to movement of the rod 231. Specifically, when the one endportion of the rod 231 is inserted into the locking groove 227, thethird elastic member 300 may be relaxed. Conversely, when the one endportion of the rod 231 is detached from the locking groove 227, thethird elastic member 300 may be contracted. When described according toanother aspect, the third elastic member 300 may be relaxed when thefirst elastic member 280 is contracted, and the second elastic member290 may be contracted when the first elastic member 280 is relaxed.

FIGS. 6A to 6C are views illustrating an operational process of thelocking unit for locking a slot in the mobile x-ray imaging apparatusaccording to an embodiment of the present disclosure. Unmarked elementsrefer to FIGS. 2 to 5.

As illustrated in FIGS. 6A to 6C, when the pressing member 210 ispressed, the pressing force of the pressing member 210 is directlytransmitted to the one or more rotating members 220. The one or morerotating members 220 rotate and protrude toward the inside of the one ormore slots 110 and 120 by the pressing force. When the one or morerotating members 220 protrude toward the inside of the one or more slots110 and 120 as described above, withdrawal of the one or more x-raydetectors 30 stored in the one or more slots 110 and 120 may beinterfered with and theft of the one or more x-ray detectors 30 may beprevented. The one end portion of the rod 231 facing therod-corresponding surface 225 moves along the rod-corresponding surface225 when the one or more rotating members 220 rotate, and rotation ofthe one or more rotating members 220 is limited when the one end portionof the rod 231 is inserted into the locking groove 227 formed at the oneor more rotating members 220. Here, the first elastic member 280 and thesecond elastic member 290 are contracted and the third elastic member300 is relaxed. The rod 231 moves upward in the first direction A by arestoration force of the third elastic member 300. The one or more slots110 and 120 may be locked by the process described above. When the oneor more slots 110 and 120 are locked, the rotation shaft 229 may bedisposed above the locking groove 227 in the first direction A.

FIGS. 7A and 7B are views illustrating an operational process of thelocking unit for unlocking a slot in the mobile x-ray imaging apparatusaccording to an embodiment of the present disclosure. Unmarked elementsshould be referred to FIGS. 2 to 5.

As illustrated in FIGS. 7A and 7B, the solenoid 233 is operated when auser inputs a command for unlocking the one or more slots 110 and 120.The rod 231 moves downward in the first direction A by the solenoid 233being operated. The one end portion of the rod 231 is detached from thelocking groove 227 when the rod 231 moves downward in the firstdirection A, and the one or more rotating members 220 are restored to astate of before being pressed by the pressing member 210 by therestoration force of the second elastic member 290. Here, the firstelastic member 280 and the second elastic member 290 are relaxed, andthe third elastic member 300 is contracted. The one or more slots 110and 120 may be unlocked by the process described above.

FIG. 8 is a perspective view illustrating a storage unit of a mobilex-ray imaging apparatus according to another embodiment of the presentdisclosure. Hereinafter, descriptions overlapping those with referenceto FIGS. 1 to 7B may be omitted. Also, like reference numerals may begiven to elements having the same name as elements described withreference to FIGS. 1 to 7B.

As illustrated in FIG. 8, a locking unit 500 may simultaneously limitwithdrawal of a plurality of x-ray detectors 30 stored in a plurality ofslots 110 and 120. That is, when the plurality of slots 110 and 120 areassumed to include a first slot 110 and a second slot 120 that abut eachother and have a partition 130 placed therebetween, withdrawal of theplurality of x-ray detectors 30 stored in the first slot 110 and thesecond slot 120 may be simultaneously limited by the single locking unit500.

The locking unit 500 may be installed in the storage unit 100.Specifically, the locking unit 500 may be installed in the partition 130to simultaneously limit withdrawal of the plurality of x-ray detectors30 stored in the first slot 110 and the second slot 120.

FIG. 9 is a perspective view illustrating a locking unit of the mobilex-ray imaging apparatus according to another embodiment of the presentdisclosure, and FIG. 10 is an exploded perspective view illustrating thelocking unit of the mobile x-ray imaging apparatus according to anotherembodiment of the present disclosure. Hereinafter, descriptionsoverlapping those with reference to FIGS. 1 to 7B may be omitted. Also,like reference numerals may be given to elements having the same name aselements described with reference to FIGS. 1 to 7B. A support member 250is omitted in FIG. 9.

As illustrated in FIGS. 9 and 10, the locking unit 500 may include apressing member 210 provided to be pressable. The pressing member 210may be provided to be pressable. The pressing member 210 may verticallymove in a first direction A according to a guide pin 213.

The locking unit 500 may further include a plurality of rotating members521 and 522. The plurality of rotating members 521 and 522 may include afirst rotating member 521 provided to rotate and protrude toward aninside of the first slot 110 and a second rotating member 522 providedto rotate and protrude toward an inside of the second slot 120. Thepressing member 210 may simultaneously press the plurality of rotatingmembers 521 and 522. Also, a pressing force of the pressing member 210may be directly transmitted to the plurality of rotating members 521 and522. The first rotating member 521 and the second rotating member 522may rotate about rotation shafts 229 extending in the second directionB. The rotation shaft 229 configured to pass through the first rotatingmember 521 and the rotation shaft 229 configured to pass through thesecond rotating member 522 may be parallel to each other.

The locking unit 500 may further include a rotation limiting unit 230configured to simultaneously limit rotation of the plurality of rotatingmembers 521 and 522. The rotation limiting unit 230 may face thepressing member 210 and the plurality of rotating members 521 and 522may be placed therebetween.

The rotation limiting unit 230 may include a rod 531. The rod 531 mayvertically move in the first direction A which is the same as a movingdirection of the pressing member 210. The rod 531 may include a firstlocking portion 531 a configured to limit rotation of the first rotatingmember 521 and a second locking portion 531 b configured to limitrotation of the second rotating member 522. Also, the rod 531 mayfurther include a connecting portion 531 c configured to connect thefirst locking portion 531 a to the second locking portion 531 b so thatthe first locking portion 531 a and the second locking portion 531 b maymove as one body.

The rotation limiting unit 230 may further include a solenoid 233coupled to the rod 531 to control movement of the rod 531 according toan electrical signal. The solenoid 233 may be connected via a cable 239to a controller configured to control whether the solenoid 233 isoperated. Because description of the solenoid 233 overlaps descriptionthereof with reference to FIGS. 1 to 7B, the description thereof will beomitted.

The rotation limiting unit 230 may further include a casing 234 in whichthe rod 531 and the solenoid 233 are mounted. Because description of thecasing 234 overlaps description thereof with reference to FIGS. 1 to 7B,the description thereof will be omitted.

As described above, the single pressing member 210 and the singlerotation limiting unit 230 may be used to simultaneously controlrotation of the plurality of rotating members 521 and 522. In this way,withdrawal of the plurality of x-ray detectors 30 stored in theplurality of slots 110 and 120 may be simultaneously limited.

The plurality of rotating members 521 and 522 may be operated to besymmetrical to each other.

FIG. 11 is a view illustrating the locking unit when a slot in themobile x-ray imaging apparatus according to another embodiment of thepresent disclosure is locked. Hereinafter, descriptions overlappingthose with reference to FIGS. 1 to 7B may be omitted. Also, likereference numerals may be given to elements having the same name aselements described with reference to FIGS. 1 to 7B.

As illustrated in FIG. 11, when the pressing member 210 is pressed, thepressing force of the pressing member 210 is simultaneously transmittedto the plurality of rotating members 521 and 522. The plurality ofrotating members 521 and 522 rotate and protrude toward the inside ofthe plurality of slots 110 and 120 by the pressing force of the pressingmember 210. The first locking portion 531 a and the second lockingportion 531 b are configured to face a rod-corresponding surface 225when the plurality of rotating members 521 and 522 rotate andrespectively move along the rod-corresponding surface 225 of the firstrotating member 521 and the rod-corresponding surface 225 of the secondrotating member 522, and rotation of the plurality of rotating members521 and 522 is simultaneously limited when the first locking portion 531a and the second locking portion 531 b are respectively inserted into alocking groove 227 of the first rotating member 521 and a locking groove227 of the second rotating member 522. Here, the first elastic member280 and the second elastic member 290 are contracted, and the thirdelastic member 300 is relaxed. The rod 531 moves upward in the firstdirection A by the restoration force of the third elastic member 300.

FIG. 12 is a view illustrating the locking unit when a slot in themobile x-ray imaging apparatus according to another embodiment of thepresent disclosure is unlocked. Hereinafter, descriptions overlappingthose with reference to FIGS. 1 to 7B may be omitted. Also, likereference numerals may be given to elements having the same name aselements described with reference to FIGS. 1 to 7B.

As illustrated in FIG. 12, the solenoid 233 is operated when a userinputs a command for unlocking the plurality of slots 110 and 120. Therod 531 moves downward in the first direction A by the solenoid 233being operated. The first locking portion 531 a and the second lockingportion 531 b are respectively detached from the locking groove 227 ofthe first rotating member 521 and the locking groove 227 of the secondrotating member 522 when the rod 531 moves downward in the firstdirection A, and the plurality of rotating member 521 and 522 arerestored to a state of before being pressed by the pressing member 210by the restoration force of the second elastic member 290. Here, thefirst elastic member 280 and the second elastic member 290 are relaxed,and the third elastic member 300 is contracted.

Although a few exemplary embodiments have been shown and described, itwould be appreciated by those skilled in the art that changes may bemade in these exemplary embodiments without departing from theprinciples and spirit of the exemplary embodiments, the scope of whichis defined in the claims and their equivalents.

The invention claimed is:
 1. A mobile x-ray imaging apparatuscomprising: an x-ray source configured to generate and radiate x-rays;one or more x-ray detectors provided to detect the x-rays radiated fromthe x-ray source; a storage bin having one or more slots in which theone or more x-ray detectors are stored; and one or more locking devicesinstalled in the storage bin to limit withdrawal of the one or morex-ray detectors stored in the one or more slots, wherein the one or morelocking devices include: a pressing member provided to be pressable; andone or more rotating members provided to be rotatable by a pressingforce of the pressing member.
 2. The mobile x-ray imaging apparatus ofclaim 1, wherein: the pressing member vertically moves in a firstdirection; and the one or more rotating members rotate about a rotationshaft extending in a second direction.
 3. The mobile x-ray imagingapparatus of claim 1, wherein: the one or more locking devices furtherinclude a rotation limiting member configured to limit rotation of theone or more rotating members; and the rotation limiting member faces thepressing member and the one or more rotating members are placed therebetween.
 4. The mobile x-ray imaging apparatus of claim 3, wherein therotation limiting member includes: a rod configured to vertically movein a first direction, which is the same as a moving direction of thepressing member; and a solenoid coupled to the rod to adjust movement ofthe rod according to an electrical signal.
 5. The mobile x-ray imagingapparatus of claim 4, wherein: each of the one or more rotating membersincludes a rod-corresponding surface configured to face the rod; and oneend portion of the rod facing the rod-corresponding surface moves alongthe rod-corresponding surface when the one or more rotating membersrotate.
 6. The mobile x-ray imaging apparatus of claim 4, wherein: therotation limiting member further includes a casing configured to havethe rod and the solenoid mounted therein and have a rod guide formed atone sidewall thereof; and a stopper that is formed to protrude from therod is configured to move vertically in the first direction and becoupled to the rod guide to limit vertical movement of the rod.
 7. Themobile x-ray imaging apparatus of claim 1, wherein: the pressing membermoves along a guide pin coupled to the pressing member to guide movementof the pressing member; and a first elastic member configured to berepeatedly contracted and relaxed according to movement of the pressingmember is provided at the guide pin.
 8. The mobile x-ray imagingapparatus of claim 1, wherein the one or more rotating members areconfigured to directly receive the pressing force of the pressing memberand provided to protrude toward an inside of the one or more slots. 9.The mobile x-ray imaging apparatus of claim of 7, wherein: the one ormore rotating members rotate about a rotation shaft configured to passthrough the one or more rotating members; and a second elastic memberconfigured to be repeatedly contracted and relaxed according to rotationof the one or more rotating members is provided at the rotation shaft.10. The mobile x-ray imaging apparatus of claim 9, wherein the one ormore locking devices further include a connecting member configured toconnect the pressing member to the rotation limiting member and have aguide pin through-hole through which the guide pin passes formedtherein.
 11. The mobile x-ray imaging apparatus of claim 9, wherein: theone or more locking devices further include a support member installedat a partition configured to divide the one or more slots; and therotation shaft passes through the support member and the one or morerotating members.
 12. The mobile x-ray imaging apparatus of claim 11,wherein: the second elastic member includes a torsion spring; one endportion of the second elastic member is fixed to one sidewall of thesupport member; and the other end portion of the second elastic memberis fixed to a protrusion formed at one surface of each of the one ormore rotating members facing the one sidewall of the support member towhich the one end portion of the second elastic member is fixed.
 13. Amobile x-ray imaging apparatus comprising: an x-ray source configured togenerate and radiate x-rays; a storage bin having a slot in which anx-ray detector is stored, wherein the x-ray detector is provided todetect the x-rays radiated from the x-ray source; and a locking deviceinstalled in the storage bin to limit withdrawal of the x-ray detectorstored in the slot, wherein the locking device includes: a pressingmember provided to be pressable; and a rotating member provided to berotatable by a pressing force of the pressing member.
 14. The mobilex-ray imaging apparatus of claim 13, wherein the rotating member isconfigured to directly receive the pressing force of the pressing memberand provided to protrude toward an inside of the slot.
 15. The mobilex-ray imaging apparatus of claim 13, wherein: the pressing membervertically moves in a first direction; and the rotating member rotatesabout a rotation shaft extending in a second direction.
 16. The mobilex-ray imaging apparatus of claim 13, wherein: the locking device furtherincludes a rotation limiting member configured to limit rotation of therotating member; and the rotation limiting member faces the pressingmember and the rotating member is placed there between.
 17. The mobilex-ray imaging apparatus of claim 16, wherein the rotation limitingmember includes: a rod configured to vertically move in a firstdirection, which is the same as a moving direction of the pressingmember; and a solenoid coupled to the rod to adjust movement of the rodaccording to an electrical signal.
 18. A method for preventingwithdrawal of an x-ray detector comprising: inserting the x-ray detectorinto a slot of a storage bin; and pressing a pressing member in a firstdirection in which the x-ray detector is inserted into the slot so thata rotating member protrudes toward an inside of the slot to preventwithdrawal of the x-ray detector inserted into the slot.
 19. The methodof claim 18, wherein the rotating member is maintained in a stateprotruding toward the inside of the slot as a rod of a rotation limitingmember moves in a second direction opposite to the first direction andinserted into a locking groove formed at the rotating member.
 20. Themethod of claim 18, wherein a pressing force of the pressing member isdirectly transmitted to the rotating member.